Difference between revisions of "Financing & Public Support of Biogas Plants"
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On principle the following can be seen as starting points for the distribution of biogas plants to such an extent that would make them macro-economically feasible and socio-politically desirable: | On principle the following can be seen as starting points for the distribution of biogas plants to such an extent that would make them macro-economically feasible and socio-politically desirable: | ||
− | |||
*'''the creation or alteration of structural conditions for individual investment decisions in favour of biogas plants, e.g. more critical control of firewood consumption and tree-felling, regulations concerning the treatment and disposal of substrates (waste water, faeces)''' | *'''the creation or alteration of structural conditions for individual investment decisions in favour of biogas plants, e.g. more critical control of firewood consumption and tree-felling, regulations concerning the treatment and disposal of substrates (waste water, faeces)''' | ||
*'''the subsidising of private and institutional community biogas plants by means of grants or inexpensive credits''' | *'''the subsidising of private and institutional community biogas plants by means of grants or inexpensive credits''' | ||
*'''the construction and operation of biogas plants as public utility enterprises especially as municipal community plants, in appropriate instances by allocation of appropriated means to the municipalities.''' | *'''the construction and operation of biogas plants as public utility enterprises especially as municipal community plants, in appropriate instances by allocation of appropriated means to the municipalities.''' | ||
− | |||
<div style="text-align: center;"><center> | <div style="text-align: center;"><center> | ||
<br/> | <br/> | ||
Line 57: | Line 55: | ||
= Further Information = | = Further Information = | ||
+ | |||
+ | == Revenues == | ||
+ | |||
+ | A biogas plant can generate revenues in the following ways: | ||
+ | |||
+ | <br/> | ||
+ | *sale of electricity | ||
+ | *sale of heat | ||
+ | *sale of gas | ||
+ | *revenues from disposal of digestion substrates | ||
+ | *sale of digestate | ||
+ | *reduction of costs for disposal of agricultural residues | ||
+ | *Carbon emission reduction ([[Climate Protection by Utilization of Biogas|CDM]]) | ||
+ | |||
+ | <br/>The principal source of revenue for biogas plants, apart from those which feed gas into a grid, is the sale of electricity. As the level of payment and the duration of the entitlement to payment are regulated by law, revenues from the sale of electricity can be projected without risk depending on the country of implementation. | ||
+ | |||
+ | In Germany, depending on the type and quantity of substrates used, the output of the plant and fulfilment of other requirements for payment of bonuses, the tariff for power generation is subject to considerable variation between roughly 8 and 30 ct/kWh. Bonuses are paid for various reasons, including for the exclusive use of energy crops and manure, meaningful use of the heat arising at the plant, use of innovative technology, and compliance with the formaldehyde limits laid down in TA Luft (cf. Section 7.3.3.3). The tariff arrangements are dealt with in detail<br/>In rare cases, a disposal fee can be charged for substrates used in the plant. However, such a possibility must be carefully examined and, if necessary, contractually secured before being factored into the cost/revenue projections. | ||
+ | |||
+ | |||
+ | |||
+ | [[Service Pack Biogas|►Return to Main Page]] | ||
+ | |||
+ | <br/> | ||
+ | |||
+ | == Financing of project implementation == | ||
+ | |||
+ | From [https://energypedia.info/index.php?title=Financing_and_public_support_for_Biogas_Plants&action=edit energypedia:] | ||
+ | |||
+ | The cost necessary for the construction of biogas plants frequently exceeds the means at the disposal of the investor, in other words he cannot cover them from his regular income or savings. This could also apply to the larger replacement investments occurring at certain intervals during the economic lifetime of the plant. Besides the non-recurring i.e. a-periodical costs, the running costs of the plant have to be borne. This solvency outflow however, is set against solvency inflow in the form of regular revenue. A solvency analysis can show how far the net solvency outflow has to be financed and how much scope there will be from net solvency inflow. Usually the construction and operation of biogas plants involve a demand for financial means which can only be covered by borrowed capital. In general the following can be seen as sources: | ||
+ | |||
+ | <br/> | ||
+ | <div style="text-align: center;"><center> | ||
+ | {| class="FCK__ShowTableBorders" cellspacing="0" cellpadding="0" | ||
+ | |- | ||
+ | | class="MENU" | | ||
+ | *'''Grants and credits from institutes for economic aid''' | ||
+ | *'''Means from the national budget of the developing country (public support)''' | ||
+ | *'''Credits from national (developing) banks''' | ||
+ | *[[Climate Protection by Utilization of Biogas|Funding from international carbon trading schemes]] | ||
+ | *'''Resources of the project initiator''' | ||
+ | *'''Fees/contributions from the user''' | ||
+ | |||
+ | |} | ||
+ | </center></div> | ||
+ | <br/>The various sources have to be individually examined for their ability to provide the means. | ||
+ | |||
+ | === Financing by credit === | ||
+ | |||
+ | When financing by credit the questions of liability and debt provisions should be clarified. The borrower should always be able to bear the possible risk or be immune to this risk by having state credit guarantees. The debt provisions should be worked out so that they conform to the development of cost and yield. Credit repayment terms are frequently much shorter than the lifetime of a project e.g. 5 years compared to 15 - 20 years. The bringing up of capital often becomes an invincible barrier for the investor. | ||
+ | |||
+ | <br/> | ||
+ | |||
+ | <br/> | ||
+ | |||
+ | === State support === | ||
+ | |||
+ | When the profitability of biogas plants are negative on a private scale, but on a national scale lead to positive results, state support measures are required. | ||
+ | |||
+ | On principle the following can be seen as starting points for the distribution of biogas plants to such an extent that would make them macro-economically feasible and socio-politically desirable: | ||
+ | |||
+ | Since the implementation of biogas plants necessitates considerable investment from public funds, sufficient public means for parallel socio-techno-economic investigations should be provided for, which allow a suitable feedback to promotion and distribution strategy. | ||
+ | |||
+ | <br/> | ||
+ | |||
+ | <br/> | ||
+ | |||
+ | = Financing of plant operation<br/> = | ||
+ | |||
+ | == Running, maintenance and repair costs == | ||
+ | |||
+ | The financing of investments and of the operation of the plant should be clearly settled at the preplanning stage. It has to be ensured that the quota derived from public funds is firmly planned in the budget. Special attention has to be paid to the question of how the running, maintenance and repair costs can be financed. Means for servicing and repairing are of essential importance and have to be available in sufficient quantity and in good time in order to make full use of the possible lifetime of the plant and also to insure the confidence of the user in the reliability of the plant. | ||
+ | |||
+ | === <br/>Economic optimisation === | ||
+ | |||
+ | <br/>Economic optimisation is aimed at reducing costs and increasing yields. Like technical optimisation, economic optimisation can be applied to all sub-processes. In this case, too, the first step is to identify the substantial cost factors so that the related costs can be reduced accordingly. Specific variables such as electricity generation costs (e.g. in €/kWh) or specific investment costs (in<br/>€/kWel inst.) serve as the basis for an initial guide to plant performance as a whole. There are comparative studies for these (for example German biogas measuring programme, ), thus enabling the overall economic performance of the plant to be graded. To conduct an in-depth study it is advisable to analyse and compare the following economic data: | ||
+ | *Operating costs | ||
+ | *Personnel costs | ||
+ | *Maintenance costs | ||
+ | *Repair costs | ||
+ | *Energy costs | ||
+ | *Cost of upkeep | ||
+ | *Investment costs (depreciation), repayment, interest | ||
+ | *Substrate costs (linked to substrate quality and substrate quantities) | ||
+ | *Revenue for generated electricity and heat | ||
+ | *Revenue for substrates | ||
+ | *Revenue for fermentation residues/fertiliser | ||
+ | |||
+ | <br/> | ||
+ | |||
+ | == Toolkit == | ||
+ | |||
+ | [https://dms.gtz.de/livelink-ger/livelink.exe?func=ll&objaction=overview&objid=72909223 Excelsheet for detailed financial calculation] | ||
+ | |||
+ | == Biogas Box == | ||
+ | |||
+ | [https://dms.gtz.de/livelink-ger/livelink.exe?func=ll&objId=72905992&objAction=browse&viewType=1 DMS folder for further reading on financing.] | ||
+ | |||
+ | <br/> | ||
+ | |||
+ | == Web == | ||
+ | |||
+ | [http://www.cd3wd.com/cd3wd_40/BIOGSHTM/EN/COSTBEN/COSTS.HTML Costs of a biogas plant] | ||
+ | |||
+ | [http://www.fluid-biogas.com/?page_id=185&lang=en Fluid biogas] | ||
+ | |||
+ | [http://giz.energypedia.info/index.php/File:Promoting_EE_via_the_financial_sector.pdf Energypedia for financing domestic biogas applications] | ||
+ | |||
+ | [http://daten.ktbl.de/biogas/showSubstrate.do?zustandReq=3#anwendung Profitability Calculator (KTBL)] | ||
+ | |||
+ | [http://de.slideshare.net/AwaisAlii/business-plan-bio-gas-11901737 Presentation on how to create a business plan for a biogas plant] | ||
+ | |||
+ | [http://www.biogaspartner.de/en/biowhat-biomethane/value-chain/sales-and-trade.html Sales and trade of Biomethane] | ||
+ | |||
+ | <br/> | ||
+ | |||
+ | == References == | ||
+ | |||
+ | [[Category:Financing_and_Funding]] | ||
+ | [[Category:Financing_Biogas]] | ||
[[Category:Biogas]] | [[Category:Biogas]] | ||
− | |||
− |
Revision as of 22:33, 20 January 2014
Overview
Sources of Financing
The cost necessary for the construction of biogas plants frequently exceeds the means at the disposal of the investor, in other words he cannot cover them from his regular income or savings. This could also apply to the larger replacement investments occurring at certain intervals during the economic lifetime of the plant. Besides the non-recurring i.e. a-periodical costs, the running costs of the plant have to be borne. This solvency outflow however, is set against solvency inflow in the form of regular revenue. A solvency analysis can show how far the net solvency outflow has to be financed and how much scope there will be from net solvency inflow. Usually the construction and operation of biogas plants involve a demand for financial means which can only be covered by borrowed capital. In general the following can be seen as sources:
|
The various sources have to be individually examined for their ability to provide the means.
Running, Maintenance and Repair Costs
The financing of investments and of the operation of the plant should be clearly settled at the preplanning stage. It has to be ensured that the quota derived from public funds is firmly planned in the budget. Special attention has to be paid to the question of how the running, maintenance and repair costs can be financed. Means for servicing and repairing are of essential importance and have to be available in sufficient quantity and in good time in order to make full use of the possible lifetime of the plant and also to insure the confidence of the user in the reliability of the plant.
Financing by Credit
When financing by credit the questions of liability and debt provisions should be clarified. The borrower should always be able to bear the possible risk or be immune to this risk by having state credit guarantees. The debt provisions should be worked out so that they conform to the development of cost and yield. Credit repayment terms are frequently much shorter than the lifetime of a project e.g. 5 years compared to 15 - 20 years. The bringing up of capital often becomes an invincible barrier for the investor.
State Support
When the profitability of biogas plants are negative on a private scale, but on a national scale lead to positive results, state support measures are required.
On principle the following can be seen as starting points for the distribution of biogas plants to such an extent that would make them macro-economically feasible and socio-politically desirable:
- the creation or alteration of structural conditions for individual investment decisions in favour of biogas plants, e.g. more critical control of firewood consumption and tree-felling, regulations concerning the treatment and disposal of substrates (waste water, faeces)
- the subsidising of private and institutional community biogas plants by means of grants or inexpensive credits
- the construction and operation of biogas plants as public utility enterprises especially as municipal community plants, in appropriate instances by allocation of appropriated means to the municipalities.
Families with Low Incomes
The more plants are extended to families with low incomes, the less can the costs for construction and operation of the plant be met by contributions from the users. On village community plants in India providing energy for the households practical experience has indicated that not even the running costs can be met by user fees. Consequently, not only the investment costs but also a proportion of the running costs has to be covered by general tax revenue. The resolution of the Indian Government provides a guideline for the extent of public support whereby from case to case 50 to 100% of the cost for community biogas plants are subsidised.
Since the implementation of biogas plants necessitates considerable investment from public funds, sufficient public means for parallel socio-techno-economic investigations should be provided for, which allow a suitable feedback to promotion and distribution strategy.
Further Information
Revenues
A biogas plant can generate revenues in the following ways:
- sale of electricity
- sale of heat
- sale of gas
- revenues from disposal of digestion substrates
- sale of digestate
- reduction of costs for disposal of agricultural residues
- Carbon emission reduction (CDM)
The principal source of revenue for biogas plants, apart from those which feed gas into a grid, is the sale of electricity. As the level of payment and the duration of the entitlement to payment are regulated by law, revenues from the sale of electricity can be projected without risk depending on the country of implementation.
In Germany, depending on the type and quantity of substrates used, the output of the plant and fulfilment of other requirements for payment of bonuses, the tariff for power generation is subject to considerable variation between roughly 8 and 30 ct/kWh. Bonuses are paid for various reasons, including for the exclusive use of energy crops and manure, meaningful use of the heat arising at the plant, use of innovative technology, and compliance with the formaldehyde limits laid down in TA Luft (cf. Section 7.3.3.3). The tariff arrangements are dealt with in detail
In rare cases, a disposal fee can be charged for substrates used in the plant. However, such a possibility must be carefully examined and, if necessary, contractually secured before being factored into the cost/revenue projections.
Financing of project implementation
From energypedia:
The cost necessary for the construction of biogas plants frequently exceeds the means at the disposal of the investor, in other words he cannot cover them from his regular income or savings. This could also apply to the larger replacement investments occurring at certain intervals during the economic lifetime of the plant. Besides the non-recurring i.e. a-periodical costs, the running costs of the plant have to be borne. This solvency outflow however, is set against solvency inflow in the form of regular revenue. A solvency analysis can show how far the net solvency outflow has to be financed and how much scope there will be from net solvency inflow. Usually the construction and operation of biogas plants involve a demand for financial means which can only be covered by borrowed capital. In general the following can be seen as sources:
|
The various sources have to be individually examined for their ability to provide the means.
Financing by credit
When financing by credit the questions of liability and debt provisions should be clarified. The borrower should always be able to bear the possible risk or be immune to this risk by having state credit guarantees. The debt provisions should be worked out so that they conform to the development of cost and yield. Credit repayment terms are frequently much shorter than the lifetime of a project e.g. 5 years compared to 15 - 20 years. The bringing up of capital often becomes an invincible barrier for the investor.
State support
When the profitability of biogas plants are negative on a private scale, but on a national scale lead to positive results, state support measures are required.
On principle the following can be seen as starting points for the distribution of biogas plants to such an extent that would make them macro-economically feasible and socio-politically desirable:
Since the implementation of biogas plants necessitates considerable investment from public funds, sufficient public means for parallel socio-techno-economic investigations should be provided for, which allow a suitable feedback to promotion and distribution strategy.
Financing of plant operation
Running, maintenance and repair costs
The financing of investments and of the operation of the plant should be clearly settled at the preplanning stage. It has to be ensured that the quota derived from public funds is firmly planned in the budget. Special attention has to be paid to the question of how the running, maintenance and repair costs can be financed. Means for servicing and repairing are of essential importance and have to be available in sufficient quantity and in good time in order to make full use of the possible lifetime of the plant and also to insure the confidence of the user in the reliability of the plant.
Economic optimisation
Economic optimisation is aimed at reducing costs and increasing yields. Like technical optimisation, economic optimisation can be applied to all sub-processes. In this case, too, the first step is to identify the substantial cost factors so that the related costs can be reduced accordingly. Specific variables such as electricity generation costs (e.g. in €/kWh) or specific investment costs (in
€/kWel inst.) serve as the basis for an initial guide to plant performance as a whole. There are comparative studies for these (for example German biogas measuring programme, ), thus enabling the overall economic performance of the plant to be graded. To conduct an in-depth study it is advisable to analyse and compare the following economic data:
- Operating costs
- Personnel costs
- Maintenance costs
- Repair costs
- Energy costs
- Cost of upkeep
- Investment costs (depreciation), repayment, interest
- Substrate costs (linked to substrate quality and substrate quantities)
- Revenue for generated electricity and heat
- Revenue for substrates
- Revenue for fermentation residues/fertiliser
Toolkit
Excelsheet for detailed financial calculation
Biogas Box
DMS folder for further reading on financing.
Web
Energypedia for financing domestic biogas applications
Profitability Calculator (KTBL)
Presentation on how to create a business plan for a biogas plant